/* * Copyright (c) 1988, 1989, 1990 The Regents of the University of California. * Copyright (c) 1988, 1989 by Adam de Boor * Copyright (c) 1989 by Berkeley Softworks * All rights reserved. * * This code is derived from software contributed to Berkeley by * Adam de Boor. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef lint static char sccsid[] = "@(#)dir.c 5.6 (Berkeley) 12/28/90"; #endif /* not lint */ /*- * dir.c -- * Directory searching using wildcards and/or normal names... * Used both for source wildcarding in the Makefile and for finding * implicit sources. * * The interface for this module is: * Dir_Init Initialize the module. * * Dir_HasWildcards Returns TRUE if the name given it needs to * be wildcard-expanded. * * Dir_Expand Given a pattern and a path, return a Lst of names * which match the pattern on the search path. * * Dir_FindFile Searches for a file on a given search path. * If it exists, the entire path is returned. * Otherwise NULL is returned. * * Dir_MTime Return the modification time of a node. The file * is searched for along the default search path. * The path and mtime fields of the node are filled * in. * * Dir_AddDir Add a directory to a search path. * * Dir_MakeFlags Given a search path and a command flag, create * a string with each of the directories in the path * preceded by the command flag and all of them * separated by a space. * * Dir_Destroy Destroy an element of a search path. Frees up all * things that can be freed for the element as long * as the element is no longer referenced by any other * search path. * Dir_ClearPath Resets a search path to the empty list. * * For debugging: * Dir_PrintDirectories Print stats about the directory cache. */ #include #include #include #include #include "make.h" #include "hash.h" /* * A search path consists of a Lst of Path structures. A Path structure * has in it the name of the directory and a hash table of all the files * in the directory. This is used to cut down on the number of system * calls necessary to find implicit dependents and their like. Since * these searches are made before any actions are taken, we need not * worry about the directory changing due to creation commands. If this * hampers the style of some makefiles, they must be changed. * * A list of all previously-read directories is kept in the * openDirectories Lst. This list is checked first before a directory * is opened. * * The need for the caching of whole directories is brought about by * the multi-level transformation code in suff.c, which tends to search * for far more files than regular make does. In the initial * implementation, the amount of time spent performing "stat" calls was * truly astronomical. The problem with hashing at the start is, * of course, that pmake doesn't then detect changes to these directories * during the course of the make. Three possibilities suggest themselves: * * 1) just use stat to test for a file's existence. As mentioned * above, this is very inefficient due to the number of checks * engendered by the multi-level transformation code. * 2) use readdir() and company to search the directories, keeping * them open between checks. I have tried this and while it * didn't slow down the process too much, it could severely * affect the amount of parallelism available as each directory * open would take another file descriptor out of play for * handling I/O for another job. Given that it is only recently * that UNIX OS's have taken to allowing more than 20 or 32 * file descriptors for a process, this doesn't seem acceptable * to me. * 3) record the mtime of the directory in the Path structure and * verify the directory hasn't changed since the contents were * hashed. This will catch the creation or deletion of files, * but not the updating of files. However, since it is the * creation and deletion that is the problem, this could be * a good thing to do. Unfortunately, if the directory (say ".") * were fairly large and changed fairly frequently, the constant * rehashing could seriously degrade performance. It might be * good in such cases to keep track of the number of rehashes * and if the number goes over a (small) limit, resort to using * stat in its place. * * An additional thing to consider is that pmake is used primarily * to create C programs and until recently pcc-based compilers refused * to allow you to specify where the resulting object file should be * placed. This forced all objects to be created in the current * directory. This isn't meant as a full excuse, just an explanation of * some of the reasons for the caching used here. * * One more note: the location of a target's file is only performed * on the downward traversal of the graph and then only for terminal * nodes in the graph. This could be construed as wrong in some cases, * but prevents inadvertent modification of files when the "installed" * directory for a file is provided in the search path. * * Another data structure maintained by this module is an mtime * cache used when the searching of cached directories fails to find * a file. In the past, Dir_FindFile would simply perform an access() * call in such a case to determine if the file could be found using * just the name given. When this hit, however, all that was gained * was the knowledge that the file existed. Given that an access() is * essentially a stat() without the copyout() call, and that the same * filesystem overhead would have to be incurred in Dir_MTime, it made * sense to replace the access() with a stat() and record the mtime * in a cache for when Dir_MTime was actually called. */ Lst dirSearchPath; /* main search path */ static Lst openDirectories; /* the list of all open directories */ /* * Variables for gathering statistics on the efficiency of the hashing * mechanism. */ static int hits, /* Found in directory cache */ misses, /* Sad, but not evil misses */ nearmisses, /* Found under search path */ bigmisses; /* Sought by itself */ typedef struct Path { char *name; /* Name of directory */ int refCount; /* Number of paths with this directory */ int hits; /* the number of times a file in this * directory has been found */ Hash_Table files; /* Hash table of files in directory */ } Path; static Path *dot; /* contents of current directory */ static Hash_Table mtimes; /* Results of doing a last-resort stat in * Dir_FindFile -- if we have to go to the * system to find the file, we might as well * have its mtime on record. XXX: If this is done * way early, there's a chance other rules will * have already updated the file, in which case * we'll update it again. Generally, there won't * be two rules to update a single file, so this * should be ok, but... */ /*- *----------------------------------------------------------------------- * Dir_Init -- * initialize things for this module * * Results: * none * * Side Effects: * some directories may be opened. *----------------------------------------------------------------------- */ void Dir_Init () { dirSearchPath = Lst_Init (FALSE); openDirectories = Lst_Init (FALSE); Hash_InitTable(&mtimes, 0); /* * Since the Path structure is placed on both openDirectories and * the path we give Dir_AddDir (which in this case is openDirectories), * we need to remove "." from openDirectories and what better time to * do it than when we have to fetch the thing anyway? */ Dir_AddDir (openDirectories, "."); dot = (Path *) Lst_DeQueue (openDirectories); /* * We always need to have dot around, so we increment its reference count * to make sure it's not destroyed. */ dot->refCount += 1; } /*- *----------------------------------------------------------------------- * DirFindName -- * See if the Path structure describes the same directory as the * given one by comparing their names. Called from Dir_AddDir via * Lst_Find when searching the list of open directories. * * Results: * 0 if it is the same. Non-zero otherwise * * Side Effects: * None *----------------------------------------------------------------------- */ static int DirFindName (p, dname) Path *p; /* Current name */ char *dname; /* Desired name */ { return (strcmp (p->name, dname)); } /*- *----------------------------------------------------------------------- * Dir_HasWildcards -- * see if the given name has any wildcard characters in it * * Results: * returns TRUE if the word should be expanded, FALSE otherwise * * Side Effects: * none *----------------------------------------------------------------------- */ Boolean Dir_HasWildcards (name) char *name; /* name to check */ { register char *cp; for (cp = name; *cp; cp++) { switch(*cp) { case '{': case '[': case '?': case '*': return (TRUE); } } return (FALSE); } /*- *----------------------------------------------------------------------- * DirMatchFiles -- * Given a pattern and a Path structure, see if any files * match the pattern and add their names to the 'expansions' list if * any do. This is incomplete -- it doesn't take care of patterns like * src/*src/*.c properly (just *.c on any of the directories), but it * will do for now. * * Results: * Always returns 0 * * Side Effects: * File names are added to the expansions lst. The directory will be * fully hashed when this is done. *----------------------------------------------------------------------- */ static int DirMatchFiles (pattern, p, expansions) char *pattern; /* Pattern to look for */ Path *p; /* Directory to search */ Lst expansions; /* Place to store the results */ { Hash_Search search; /* Index into the directory's table */ Hash_Entry *entry; /* Current entry in the table */ char *f; /* Current entry in the directory */ Boolean isDot; /* TRUE if the directory being searched is . */ isDot = (*p->name == '.' && p->name[1] == '\0'); for (entry = Hash_EnumFirst(&p->files, &search); entry != (Hash_Entry *)NULL; entry = Hash_EnumNext(&search)) { /* * See if the file matches the given pattern. Note we follow the UNIX * convention that dot files will only be found if the pattern * begins with a dot (note also that as a side effect of the hashing * scheme, .* won't match . or .. since they aren't hashed). */ if (Str_Match(entry->name, pattern) && ((entry->name[0] != '.') || (pattern[0] == '.'))) { (void)Lst_AtEnd(expansions, (isDot ? strdup(entry->name) : str_concat(p->name, entry->name, STR_ADDSLASH))); } } return (0); } /*- *----------------------------------------------------------------------- * DirExpandCurly -- * Expand curly braces like the C shell. Does this recursively. * Note the special case: if after the piece of the curly brace is * done there are no wildcard characters in the result, the result is * placed on the list WITHOUT CHECKING FOR ITS EXISTENCE. * * Results: * None. * * Side Effects: * The given list is filled with the expansions... * *----------------------------------------------------------------------- */ static void DirExpandCurly(word, brace, path, expansions) char *word; /* Entire word to expand */ char *brace; /* First curly brace in it */ Lst path; /* Search path to use */ Lst expansions; /* Place to store the expansions */ { char *end; /* Character after the closing brace */ char *cp; /* Current position in brace clause */ char *start; /* Start of current piece of brace clause */ int bracelevel; /* Number of braces we've seen. If we see a * right brace when this is 0, we've hit the * end of the clause. */ char *file; /* Current expansion */ int otherLen; /* The length of the other pieces of the * expansion (chars before and after the * clause in 'word') */ char *cp2; /* Pointer for checking for wildcards in * expansion before calling Dir_Expand */ start = brace+1; /* * Find the end of the brace clause first, being wary of nested brace * clauses. */ for (end = start, bracelevel = 0; *end != '\0'; end++) { if (*end == '{') { bracelevel++; } else if ((*end == '}') && (bracelevel-- == 0)) { break; } } if (*end == '\0') { Error("Unterminated {} clause \"%s\"", start); return; } else { end++; } otherLen = brace - word + strlen(end); for (cp = start; cp < end; cp++) { /* * Find the end of this piece of the clause. */ bracelevel = 0; while (*cp != ',') { if (*cp == '{') { bracelevel++; } else if ((*cp == '}') && (bracelevel-- <= 0)) { break; } cp++; } /* * Allocate room for the combination and install the three pieces. */ file = emalloc(otherLen + cp - start + 1); if (brace != word) { strncpy(file, word, brace-word); } if (cp != start) { strncpy(&file[brace-word], start, cp-start); } strcpy(&file[(brace-word)+(cp-start)], end); /* * See if the result has any wildcards in it. If we find one, call * Dir_Expand right away, telling it to place the result on our list * of expansions. */ for (cp2 = file; *cp2 != '\0'; cp2++) { switch(*cp2) { case '*': case '?': case '{': case '[': Dir_Expand(file, path, expansions); goto next; } } if (*cp2 == '\0') { /* * Hit the end w/o finding any wildcards, so stick the expansion * on the end of the list. */ (void)Lst_AtEnd(expansions, file); } else { next: free(file); } start = cp+1; } } /*- *----------------------------------------------------------------------- * DirExpandInt -- * Internal expand routine. Passes through the directories in the * path one by one, calling DirMatchFiles for each. NOTE: This still * doesn't handle patterns in directories... * * Results: * None. * * Side Effects: * Things are added to the expansions list. * *----------------------------------------------------------------------- */ static void DirExpandInt(word, path, expansions) char *word; /* Word to expand */ Lst path; /* Path on which to look */ Lst expansions; /* Place to store the result */ { LstNode ln; /* Current node */ Path *p; /* Directory in the node */ if (Lst_Open(path) == SUCCESS) { while ((ln = Lst_Next(path)) != NILLNODE) { p = (Path *)Lst_Datum(ln); DirMatchFiles(word, p, expansions); } Lst_Close(path); } } /*- *----------------------------------------------------------------------- * DirPrintWord -- * Print a word in the list of expansions. Callback for Dir_Expand * when DEBUG(DIR), via Lst_ForEach. * * Results: * === 0 * * Side Effects: * The passed word is printed, followed by a space. * *----------------------------------------------------------------------- */ static int DirPrintWord(word) char *word; { printf("%s ", word); return(0); } /*- *----------------------------------------------------------------------- * Dir_Expand -- * Expand the given word into a list of words by globbing it looking * in the directories on the given search path. * * Results: * A list of words consisting of the files which exist along the search * path matching the given pattern. * * Side Effects: * Directories may be opened. Who knows? *----------------------------------------------------------------------- */ void Dir_Expand (word, path, expansions) char *word; /* the word to expand */ Lst path; /* the list of directories in which to find * the resulting files */ Lst expansions; /* the list on which to place the results */ { char *cp; if (DEBUG(DIR)) { printf("expanding \"%s\"...", word); } cp = index(word, '{'); if (cp) { DirExpandCurly(word, cp, path, expansions); } else { cp = index(word, '/'); if (cp) { /* * The thing has a directory component -- find the first wildcard * in the string. */ for (cp = word; *cp; cp++) { if (*cp == '?' || *cp == '[' || *cp == '*' || *cp == '{') { break; } } if (*cp == '{') { /* * This one will be fun. */ DirExpandCurly(word, cp, path, expansions); return; } else if (*cp != '\0') { /* * Back up to the start of the component */ char *dirpath; while (cp > word && *cp != '/') { cp--; } if (cp != word) { /* * If the glob isn't in the first component, try and find * all the components up to the one with a wildcard. */ *cp = '\0'; dirpath = Dir_FindFile(word, path); *cp = '/'; /* * dirpath is null if can't find the leading component * XXX: Dir_FindFile won't find internal components. * i.e. if the path contains ../Etc/Object and we're * looking for Etc, it won't be found. Ah well. * Probably not important. */ if (dirpath != (char *)NULL) { path = Lst_Init(FALSE); Dir_AddDir(path, dirpath); DirExpandInt(cp+1, path, expansions); Lst_Destroy(path, NOFREE); } } else { /* * Start the search from the local directory */ DirExpandInt(word, path, expansions); } } else { /* * Return the file -- this should never happen. */ DirExpandInt(word, path, expansions); } } else { /* * First the files in dot */ DirMatchFiles(word, dot, expansions); /* * Then the files in every other directory on the path. */ DirExpandInt(word, path, expansions); } } if (DEBUG(DIR)) { Lst_ForEach(expansions, DirPrintWord, NULL); putchar('\n'); } } /*- *----------------------------------------------------------------------- * Dir_FindFile -- * Find the file with the given name along the given search path. * * Results: * The path to the file or NULL. This path is guaranteed to be in a * different part of memory than name and so may be safely free'd. * * Side Effects: * If the file is found in a directory which is not on the path * already (either 'name' is absolute or it is a relative path * [ dir1/.../dirn/file ] which exists below one of the directories * already on the search path), its directory is added to the end * of the path on the assumption that there will be more files in * that directory later on. Sometimes this is true. Sometimes not. *----------------------------------------------------------------------- */ char * Dir_FindFile (name, path) char *name; /* the file to find */ Lst path; /* the Lst of directories to search */ { register char *p1; /* pointer into p->name */ register char *p2; /* pointer into name */ LstNode ln; /* a list element */ register char *file; /* the current filename to check */ register Path *p; /* current path member */ register char *cp; /* index of first slash, if any */ Boolean hasSlash; /* true if 'name' contains a / */ struct stat stb; /* Buffer for stat, if necessary */ Hash_Entry *entry; /* Entry for mtimes table */ /* * Find the final component of the name and note whether it has a * slash in it (the name, I mean) */ cp = rindex (name, '/'); if (cp) { hasSlash = TRUE; cp += 1; } else { hasSlash = FALSE; cp = name; } if (DEBUG(DIR)) { printf("Searching for %s...", name); } /* * No matter what, we always look for the file in the current directory * before anywhere else and we *do not* add the ./ to it if it exists. * This is so there are no conflicts between what the user specifies * (fish.c) and what pmake finds (./fish.c). */ if ((!hasSlash || (cp - name == 2 && *name == '.')) && (Hash_FindEntry (&dot->files, cp) != (Hash_Entry *)NULL)) { if (DEBUG(DIR)) { printf("in '.'\n"); } hits += 1; dot->hits += 1; return (strdup (name)); } if (Lst_Open (path) == FAILURE) { if (DEBUG(DIR)) { printf("couldn't open path, file not found\n"); } misses += 1; return ((char *) NULL); } /* * We look through all the directories on the path seeking one which * contains the final component of the given name and whose final * component(s) match the name's initial component(s). If such a beast * is found, we concatenate the directory name and the final component * and return the resulting string. If we don't find any such thing, * we go on to phase two... */ while ((ln = Lst_Next (path)) != NILLNODE) { p = (Path *) Lst_Datum (ln); if (DEBUG(DIR)) { printf("%s...", p->name); } if (Hash_FindEntry (&p->files, cp) != (Hash_Entry *)NULL) { if (DEBUG(DIR)) { printf("here..."); } if (hasSlash) { /* * If the name had a slash, its initial components and p's * final components must match. This is false if a mismatch * is encountered before all of the initial components * have been checked (p2 > name at the end of the loop), or * we matched only part of one of the components of p * along with all the rest of them (*p1 != '/'). */ p1 = p->name + strlen (p->name) - 1; p2 = cp - 2; while (p2 >= name && *p1 == *p2) { p1 -= 1; p2 -= 1; } if (p2 >= name || (p1 >= p->name && *p1 != '/')) { if (DEBUG(DIR)) { printf("component mismatch -- continuing..."); } continue; } } file = str_concat (p->name, cp, STR_ADDSLASH); if (DEBUG(DIR)) { printf("returning %s\n", file); } Lst_Close (path); p->hits += 1; hits += 1; return (file); } else if (hasSlash) { /* * If the file has a leading path component and that component * exactly matches the entire name of the current search * directory, we assume the file doesn't exist and return NULL. */ for (p1 = p->name, p2 = name; *p1 && *p1 == *p2; p1++, p2++) { continue; } if (*p1 == '\0' && p2 == cp - 1) { if (DEBUG(DIR)) { printf("must be here but isn't -- returing NULL\n"); } Lst_Close (path); return ((char *) NULL); } } } /* * We didn't find the file on any existing members of the directory. * If the name doesn't contain a slash, that means it doesn't exist. * If it *does* contain a slash, however, there is still hope: it * could be in a subdirectory of one of the members of the search * path. (eg. /usr/include and sys/types.h. The above search would * fail to turn up types.h in /usr/include, but it *is* in * /usr/include/sys/types.h) If we find such a beast, we assume there * will be more (what else can we assume?) and add all but the last * component of the resulting name onto the search path (at the * end). This phase is only performed if the file is *not* absolute. */ if (!hasSlash) { if (DEBUG(DIR)) { printf("failed.\n"); } misses += 1; return ((char *) NULL); } if (*name != '/') { Boolean checkedDot = FALSE; if (DEBUG(DIR)) { printf("failed. Trying subdirectories..."); } (void) Lst_Open (path); while ((ln = Lst_Next (path)) != NILLNODE) { p = (Path *) Lst_Datum (ln); if (p != dot) { file = str_concat (p->name, name, STR_ADDSLASH); } else { /* * Checking in dot -- DON'T put a leading ./ on the thing. */ file = strdup(name); checkedDot = TRUE; } if (DEBUG(DIR)) { printf("checking %s...", file); } if (stat (file, &stb) == 0) { if (DEBUG(DIR)) { printf("got it.\n"); } Lst_Close (path); /* * We've found another directory to search. We know there's * a slash in 'file' because we put one there. We nuke it after * finding it and call Dir_AddDir to add this new directory * onto the existing search path. Once that's done, we restore * the slash and triumphantly return the file name, knowing * that should a file in this directory every be referenced * again in such a manner, we will find it without having to do * numerous numbers of access calls. Hurrah! */ cp = rindex (file, '/'); *cp = '\0'; Dir_AddDir (path, file); *cp = '/'; /* * Save the modification time so if it's needed, we don't have * to fetch it again. */ if (DEBUG(DIR)) { printf("Caching %s for %s\n", Targ_FmtTime(stb.st_mtime), file); } entry = Hash_CreateEntry(&mtimes, (ClientData)file, (Boolean *)NULL); Hash_SetValue(entry, stb.st_mtime); nearmisses += 1; return (file); } else { free (file); } } if (DEBUG(DIR)) { printf("failed. "); } Lst_Close (path); if (checkedDot) { /* * Already checked by the given name, since . was in the path, * so no point in proceeding... */ if (DEBUG(DIR)) { printf("Checked . already, returning NULL\n"); } return(NULL); } } /* * Didn't find it that way, either. Sigh. Phase 3. Add its directory * onto the search path in any case, just in case, then look for the * thing in the hash table. If we find it, grand. We return a new * copy of the name. Otherwise we sadly return a NULL pointer. Sigh. * Note that if the directory holding the file doesn't exist, this will * do an extra search of the final directory on the path. Unless something * weird happens, this search won't succeed and life will be groovy. * * Sigh. We cannot add the directory onto the search path because * of this amusing case: * $(INSTALLDIR)/$(FILE): $(FILE) * * $(FILE) exists in $(INSTALLDIR) but not in the current one. * When searching for $(FILE), we will find it in $(INSTALLDIR) * b/c we added it here. This is not good... */ #ifdef notdef cp[-1] = '\0'; Dir_AddDir (path, name); cp[-1] = '/'; bigmisses += 1; ln = Lst_Last (path); if (ln == NILLNODE) { return ((char *) NULL); } else { p = (Path *) Lst_Datum (ln); } if (Hash_FindEntry (&p->files, cp) != (Hash_Entry *)NULL) { return (strdup (name)); } else { return ((char *) NULL); } #else /* !notdef */ if (DEBUG(DIR)) { printf("Looking for \"%s\"...", name); } bigmisses += 1; entry = Hash_FindEntry(&mtimes, name); if (entry != (Hash_Entry *)NULL) { if (DEBUG(DIR)) { printf("got it (in mtime cache)\n"); } return(strdup(name)); } else if (stat (name, &stb) == 0) { entry = Hash_CreateEntry(&mtimes, name, (Boolean *)NULL); if (DEBUG(DIR)) { printf("Caching %s for %s\n", Targ_FmtTime(stb.st_mtime), name); } Hash_SetValue(entry, stb.st_mtime); return (strdup (name)); } else { if (DEBUG(DIR)) { printf("failed. Returning NULL\n"); } return ((char *)NULL); } #endif /* notdef */ } /*- *----------------------------------------------------------------------- * Dir_MTime -- * Find the modification time of the file described by gn along the * search path dirSearchPath. * * Results: * The modification time or 0 if it doesn't exist * * Side Effects: * The modification time is placed in the node's mtime slot. * If the node didn't have a path entry before, and Dir_FindFile * found one for it, the full name is placed in the path slot. *----------------------------------------------------------------------- */ int Dir_MTime (gn) GNode *gn; /* the file whose modification time is * desired */ { char *fullName; /* the full pathname of name */ struct stat stb; /* buffer for finding the mod time */ Hash_Entry *entry; if (gn->type & OP_ARCHV) { return Arch_MTime (gn); } else if (gn->path == (char *)NULL) { fullName = Dir_FindFile (gn->name, dirSearchPath); } else { fullName = gn->path; } if (fullName == (char *)NULL) { fullName = gn->name; } entry = Hash_FindEntry(&mtimes, fullName); if (entry != (Hash_Entry *)NULL) { /* * Only do this once -- the second time folks are checking to * see if the file was actually updated, so we need to actually go * to the file system. */ if (DEBUG(DIR)) { printf("Using cached time %s for %s\n", Targ_FmtTime(Hash_GetValue(entry)), fullName); } stb.st_mtime = (time_t)Hash_GetValue(entry); Hash_DeleteEntry(&mtimes, entry); } else if (stat (fullName, &stb) < 0) { if (gn->type & OP_MEMBER) { return Arch_MemMTime (gn); } else { stb.st_mtime = 0; } } if (fullName && gn->path == (char *)NULL) { gn->path = fullName; } gn->mtime = stb.st_mtime; return (gn->mtime); } /*- *----------------------------------------------------------------------- * Dir_AddDir -- * Add the given name to the end of the given path. The order of * the arguments is backwards so ParseDoDependency can do a * Lst_ForEach of its list of paths... * * Results: * none * * Side Effects: * A structure is added to the list and the directory is * read and hashed. *----------------------------------------------------------------------- */ void Dir_AddDir (path, name) Lst path; /* the path to which the directory should be * added */ char *name; /* the name of the directory to add */ { LstNode ln; /* node in case Path structure is found */ register Path *p; /* pointer to new Path structure */ DIR *d; /* for reading directory */ register struct direct *dp; /* entry in directory */ Hash_Entry *he; char *fName; ln = Lst_Find (openDirectories, (ClientData)name, DirFindName); if (ln != NILLNODE) { p = (Path *)Lst_Datum (ln); if (Lst_Member(path, (ClientData)p) == NILLNODE) { p->refCount += 1; (void)Lst_AtEnd (path, (ClientData)p); } } else { if (DEBUG(DIR)) { printf("Caching %s...", name); fflush(stdout); } if ((d = opendir (name)) != (DIR *) NULL) { p = (Path *) emalloc (sizeof (Path)); p->name = strdup (name); p->hits = 0; p->refCount = 1; Hash_InitTable (&p->files, -1); /* * Skip the first two entries -- these will *always* be . and .. */ (void)readdir(d); (void)readdir(d); while ((dp = readdir (d)) != (struct direct *) NULL) { #ifdef sun /* * The sun directory library doesn't check for a 0 inode * (0-inode slots just take up space), so we have to do * it ourselves. */ if (dp->d_fileno == 0) { continue; } #endif sun (void)Hash_CreateEntry(&p->files, dp->d_name, (Boolean *)NULL); } (void) closedir (d); (void)Lst_AtEnd (openDirectories, (ClientData)p); (void)Lst_AtEnd (path, (ClientData)p); } if (DEBUG(DIR)) { printf("done\n"); } } } /*- *----------------------------------------------------------------------- * Dir_CopyDir -- * Callback function for duplicating a search path via Lst_Duplicate. * Ups the reference count for the directory. * * Results: * Returns the Path it was given. * * Side Effects: * The refCount of the path is incremented. * *----------------------------------------------------------------------- */ ClientData Dir_CopyDir(p) Path *p; /* Directory descriptor to copy */ { p->refCount += 1; return ((ClientData)p); } /*- *----------------------------------------------------------------------- * Dir_MakeFlags -- * Make a string by taking all the directories in the given search * path and preceding them by the given flag. Used by the suffix * module to create variables for compilers based on suffix search * paths. * * Results: * The string mentioned above. Note that there is no space between * the given flag and each directory. The empty string is returned if * Things don't go well. * * Side Effects: * None *----------------------------------------------------------------------- */ char * Dir_MakeFlags (flag, path) char *flag; /* flag which should precede each directory */ Lst path; /* list of directories */ { char *str; /* the string which will be returned */ char *tstr; /* the current directory preceded by 'flag' */ LstNode ln; /* the node of the current directory */ Path *p; /* the structure describing the current directory */ str = strdup (""); if (Lst_Open (path) == SUCCESS) { while ((ln = Lst_Next (path)) != NILLNODE) { p = (Path *) Lst_Datum (ln); tstr = str_concat (flag, p->name, 0); str = str_concat (str, tstr, STR_ADDSPACE | STR_DOFREE); } Lst_Close (path); } return (str); } /*- *----------------------------------------------------------------------- * Dir_Destroy -- * Nuke a directory descriptor, if possible. Callback procedure * for the suffixes module when destroying a search path. * * Results: * None. * * Side Effects: * If no other path references this directory (refCount == 0), * the Path and all its data are freed. * *----------------------------------------------------------------------- */ void Dir_Destroy (p) Path *p; /* The directory descriptor to nuke */ { Hash_Search thing1; Hash_Entry *thing2; p->refCount -= 1; if (p->refCount == 0) { LstNode ln; ln = Lst_Member (openDirectories, (ClientData)p); (void) Lst_Remove (openDirectories, ln); Hash_DeleteTable (&p->files); free((Address)p->name); free((Address)p); } } /*- *----------------------------------------------------------------------- * Dir_ClearPath -- * Clear out all elements of the given search path. This is different * from destroying the list, notice. * * Results: * None. * * Side Effects: * The path is set to the empty list. * *----------------------------------------------------------------------- */ void Dir_ClearPath(path) Lst path; /* Path to clear */ { Path *p; while (!Lst_IsEmpty(path)) { p = (Path *)Lst_DeQueue(path); Dir_Destroy(p); } } /*- *----------------------------------------------------------------------- * Dir_Concat -- * Concatenate two paths, adding the second to the end of the first. * Makes sure to avoid duplicates. * * Results: * None * * Side Effects: * Reference counts for added dirs are upped. * *----------------------------------------------------------------------- */ void Dir_Concat(path1, path2) Lst path1; /* Dest */ Lst path2; /* Source */ { LstNode ln; Path *p; for (ln = Lst_First(path2); ln != NILLNODE; ln = Lst_Succ(ln)) { p = (Path *)Lst_Datum(ln); if (Lst_Member(path1, (ClientData)p) == NILLNODE) { p->refCount += 1; (void)Lst_AtEnd(path1, (ClientData)p); } } } /********** DEBUG INFO **********/ Dir_PrintDirectories() { LstNode ln; Path *p; printf ("#*** Directory Cache:\n"); printf ("# Stats: %d hits %d misses %d near misses %d losers (%d%%)\n", hits, misses, nearmisses, bigmisses, (hits+bigmisses+nearmisses ? hits * 100 / (hits + bigmisses + nearmisses) : 0)); printf ("# %-20s referenced\thits\n", "directory"); if (Lst_Open (openDirectories) == SUCCESS) { while ((ln = Lst_Next (openDirectories)) != NILLNODE) { p = (Path *) Lst_Datum (ln); printf ("# %-20s %10d\t%4d\n", p->name, p->refCount, p->hits); } Lst_Close (openDirectories); } } static int DirPrintDir (p) Path *p; { printf ("%s ", p->name); return (0); } Dir_PrintPath (path) Lst path; { Lst_ForEach (path, DirPrintDir, (ClientData)0); }